DeterminationoftheplatinumconcentrationofaPt/silicananocompositedecoratedwithultrasmallPtnanoparticlesusingsingleparticleinductivelycoupledplasmamassspectrometry PAPER JAAS

Determination of the platinum concentration of a Pt/silica nanocomposite decorated with ultra small Pt nanoparticles using single particle inductively coupled plasma mass spectrometry

Andr´as S´api,^aAlbert K´eri,^bIldik ´o K´alomista,^bDorina G. Dob ´o,^aAkos Szamosv¨´ olgyi,^a Kopp´any L. Juh´asz,^aAkos Kukovecz,´ ^acZolt´an K ´onya ^adand G´abor Galb´acs *^b

In this study, the performance offive analytical techniques applicable to the determination of the load concentration of ultra small nanoparticles in a Pt/SiO2nanocomposite was critically evaluated. Four of the techniques (SEM-EDS, TEM imaging, XPS and solution-mode ICP-MS) are often used for the characterization of nanoparticles, whereas single particle ICP-MS (spICP-MS) is an upcoming, novel methodology. After experimentally testing and discussing the pros and cons of each analytical technique, it was found that spICP-MS is one of the most accurate, precise and practical techniques for the analysis of nanocomposites. This technique works directly with dispersions, the measurement only takes a few minutes, it gives highly reliable results, largely free from interference from precursor residues and can also provide additional information about the particles. Although the individual measurement of ultra small nanoparticles is not yet possible by spICP-MS, the cumulative signal from such load particles in a nanocomposite allows the accurate determination of the load concentration. The spICP-MS result was concordant with the result obtained by TEM imaging, whereas SEM-EDS, XPS and solution-mode ICP- MS strongly overestimated the concentration.

1. Introduction

Novel metal/metal–oxide nanocomposites are in the focus of intense fundamental research, not only due to their unique characteristics, but also because of their already found several industrial uses in the area of medicine, sensors, energy storage, structural materials or as heterogeneous catalysts for the pro- cessing of chemicals or environmental pollutants. The reliable and quick characterization of the synthesized nanomaterials is obviously crucial both in terms of morphology and structure and composition. One of the key parameters assessed is the relative concentration (wt%) of the active metal and the sup- porting metal–oxide nanoparticle, as this has signicant inu- ence on the activity, selectivity and performance, as was shown e.g.in heterogeneous catalysis,^1,2sensors,³electrochemical⁴or fuel cell⁵research. For the determination of the concentration of the active metallic component, solution-mode inductively

coupled plasma mass spectrometry (ICP-MS),^6–8scanning elec- tron microscopy coupled with energy dispersive spectroscopy (SEM-EDS)^9,10 or X-ray photoelectron spectroscopy (XPS)¹¹ is typically used in the literature.

Single particle, or particle-mode, ICP-MS (spICP-MS) is a novel nanoparticle (NP) characterization technique, which is recently gaining increasing attention in the literature owing to its versatility and high throughput.^12–15 In this technique, sensitive ICP-MS spectrometers are used in the time-resolved mode for the measurement of dilute nanodispersions (particle concentrations less than 10⁵ mL¹ are adequate). The nano- particles get atomized and ionized in the plasma. The signal from one of the constituting elements is monitored as a func- tion of time, thus each detected NP will produce a narrow signal peak (a few hundred ms duration), the height of which is proportional to the mass of the analyte present in the NP. Aer the statistical evaluation of the signal time prole and assuming a spherical NP geometry, information can be obtained about not only the elemental (isotopic) composition of the NPs, but also their characteristic size and distribution, as well as the particle concentration. The measurement is fast (takes only a couple of minutes) and the required sample volume is very small. For metallic NPs, size detection limits ranging from 10 to 30 nm and upper detectable size limits around or above a few hundred nm are typically reported.^16–19 This technique is

aDepartment of Applied and Environmental Chemistry, University of Szeged, Rerrich B´ela Square 1, 6720 Szeged, Hungary

bDepartment of Inorganic and Analytical Chemistry, University of Szeged, D´om Square 7, 6720 Szeged, Hungary. E-mail: galbx@chem.u-szeged.hu

cMTA-SZTE“Lend¨ulet”Porous Nanocomposites Research Group, Rerrich B´ela Square 1, H-6720 Szeged, Hungary

dMTA-SZTE Reaction Kinetics and Surface Chemistry Research Group, Rerrich B´ela Square 1, H-6720 Szeged, Hungary

Cite this:J. Anal. At. Spectrom., 2017, 32, 996

Received 27th January 2017 Accepted 23rd March 2017 DOI: 10.1039/c7ja00039a rsc.li/jaas

JAAS

PAPER

diameter of the two particles is over 200, and the loading is low (<1 wt%). A critical performance comparison is provided with other well established NP characterization methods, such as transmission electron microscopy (TEM), SEM-EDS, solution- mode ICP-MS and XPS.

2. Experimental section

2.1. Synthesis and morphology of the particles

Synthesis of St¨ober silica particles. Silica particles were prepared through a process based on the St¨ober method,²⁸ using tetraethoxysilane (TEOS) as the precursor. The synthesis was carried out by mixing an ethanolic TEOS solution (17 mL TEOS dissolved in 200 mL ethanol) and an ethanolic ammonia solution (100 mL ammonia-solution of 25 wt% concentration mixed with 70 mL distilled water and 110 mL ethanol). The obtained dispersion was then stirred for 24 h. The precipitate was washed and collected by centrifugation and then nally dried at 60C for 12 h. Individual spheres with a size of 449 76 nm, as measured by SEM, were obtained, however a small amount of aggregates of 2–3 spheres was also observed.

Synthesis of ultra small Pt nanoparticles.For the synthesis of ultra small Pt NPs, 29 mg of PtCl4and 50 mg of NaOH were dissolved in two separate portions of 2.5 mL ethylene glycol. The solutions were then mixed and heated to 160C. The temper- ature of the mixture was held constant for 3 hours under an Ar atmosphere. Aer cooling, 2.5 mL of a 1 M HCl solution was added to the black suspension and the resulting NPs were collected by centrifugation. The NPs were re-dispersed in 10 mL of 2.1 mg mL¹ polyvinylpyrrolidone (PVP, M_w ¼ 40.000) in ethanol with ultrasonication. The NPs werenally washed by repeatedly performing hexane precipitation/ethanol re- dispersion cycles. The morphology of the Pt NPs was studied by TEM and they were found to be spherical with a narrow size distribution (1.6 0.5 nm). The electron diffraction pattern showed the presence of the face-centered cubic (fcc) phase of the metallic platinum.

Synthesis of Pt nanoparticles.The larger Pt NPs used in the spICP-MS size calibration process were synthesized by a multi- step seed-mediated method described by Bigallet al.²⁹For the preparation of seed particles, H₂PtCl₆$6H2O solution (0.2 wt%) was added to 400 mL boiling distilled water under continuous stirring. The next step was the addition of a 10 mL solution of Na-citrate (1%) and citric acid (0.05%) buffer, followed by homogenization and the addition of 5 mL 0.08% NaBH₄in the above-mentioned Na-citrate–citric acid buffer. The suspension was then reuxed for 10 minutes and cooled down to room temperature. The seed particles produced by using this

40.7 nm, 51.5 nm and 58.2 nm.

Preparation of the Pt/SiO2 nanocomposite particles. The 1.6 nm Pt NPs and the St¨ober silica particles were mixed together in ethanol and sonicated in an ultrasonic bath (40 kHz, 80 W) for 3 hours. The nanocomposite particles were then collected by centrifugation. The products were washed with ethanol three times before they were dried at 80C overnight.

Beside homogeneously distributed Pt NPs, small islands of separate particles were also observed by TEM on the surface of the silica particles. Fig. 1 and its insets show the electron microscopy images of the 1.6 nm Pt NPs, the silica supported NPs and the Pt/SiO₂nanocomposite NPs, respectively.

2.2. Instrumentation and data evaluation

The morphology of the pure Pt nanoparticles and St¨ober silica, as well as the Pt/silica nanocomposites, was investigated by using a TEM (FEI Tecnai G²20 X-TWIN operating at 200 kV) and a SEM (Hitachi S-4700 operating at 20 kV, also equipped with a R¨ontec energy dispersive spectrometer with a 12 mm working distance). The crystal structure of the silica was examined by X- ray Diffraction (XRD, Rigaku MiniFlex II Desktop Diffractometer operating with a Cu K_asource (l¼0.1542 nm) at 30 kV and 15 mA). The density of the particles was measured by the N2gas adsorption method using a Quantachrome NOVA 3000e gas sorption instrument.

The concentration of the Pt nanoparticles anchored onto the surface of the St¨ober silica spheres in the nanocomposite was determined by using ICP-MS, XPS, SEM-EDS measurements and TEM imaging. The measurement conditions and data evalua- tion approaches employed are described below in detail.

X-ray photoelectron spectroscopy. X-ray photoelectron spectra were recorded using a SPECS instrument equipped with a PHOIBOS 150 MCD 9 hemispherical electron energy analyzer, using Al K_a radiation (hn ¼ 1486.6 eV). The X-ray gun was operated at 210 W (14 kV, 15 mA). The analyzer was operated in the FAT mode, with the pass energy set to 20 eV. The step size was 25 meV and the collection time in one channel was 250 ms.

Typically, 5–10 scans were added up to acquire a single spec- trum. Energy referencing was not applied. In all cases the powder-like samples were evenly laid out on one side of a double-sided adhesive tape, the other side being attached to the sample holder of the XPS instrument. The samples were evacuated at room temperature and then inserted into the analysis chamber of the XPS instrument.

Solution-mode inductively coupled plasma mass spectrom- etry. An Agilent Technologies 7700X ICP-MS instrument was used in all ICP-MS experiments. Sample introduction was

performed by using an Agilent I-AS autosampler and a Micro Mist pneumatic nebulizer equipped with a Peltier-cooled Scott- type spray chamber. The sample uptake rate was 400mL min¹. The ICP plasma and interface parameters were set up according to standard conditions (RF forward power: 1550 W, argon carrier gasow rate: 1.05 L min¹, sampling depth: 8.0 mm), and then ane tuning was performed using solutions supplied by Agilent (No. G1820-60410) and special attention was paid to the optimization of the plasma sampling depth. All measure- ments were performed by monitoring the signal of the ¹⁹⁵Pt isotope. In order to avoid possible interference from HfO in the multielement solution standard used for calibration, the measurements were performed in He mode of the collision cell.

It is also worth considering that even if the HfO interference would increase the Pt signals due to the Hf content of the solution standard, it could only cause a negative error in the Pt concentration result, since the samples contain no Hf. The labware (PE autosampler vials, certied PMP volumetricasks, etc.) was thoroughly cleaned before use with dilute ultratrace quality hydrochloric and nitric acid. The sample preparation procedure was optimized for the complete dissolution of the Pt content of the nanocomposite. Several sample dissolution approaches of stepwisely increasing aggressivity and duration (direct dispersion in water, 30 min sonication in water, 30 min sonication in HCl, and 30 min digestion at 130C in 3 : 1 HCl–

HNO3) were tested and the one producing the highest Pt concentration measurable by solution-mode ICP-MS analysis was chosen as the optimal one (digestion in boiling 3 : 1 HCl–

HNO3). A further increase in the duration of acid treatment (from 30 min to 120 min) resulted in no further signicant increase in the Pt concentration measured.

Particle-mode inductively coupled plasma mass spectrom- etry.For spICP-MS measurements, the ICP-MS instrument was set up as described above for solution-mode measurements, except that the data acquisition soware was used in Time Resolved Analysis (TRA) mode, with the integration time set to 10 ms. This relatively long dwell time was chosen in consider- ation of the large (ca. 450 nm) silica carrier nanoparticle, thereby ensuring that the complete Pt signal peak produced by each nanocomposite particle is collected. All nanodispersions were diluted to less than 10⁴mL¹particle concentration, a ten

times lower value than typical in spICP-MS, in order to completely avoid any NP signal peak overlaps. Data evaluation in spICP-MS was performed on the histograms (frequency- count diagrams) produced from the time-resolved signal traces, as described in ref. 15. Data processing was performed using Agilent MassHunter (Santa Clara, California, USA) and OriginLab Origin (Northampton, Massachusetts, USA) soware.

Transmission electron microscopy imaging.The Pt concen- tration of the nanocomposite was determined by this method via the counting of the load particles on the surface of the support particles. TEM measurement conditions were as described earlier. Since only a portion of the surface of the large silica support particles could be observed in all micrographs due to the large magnication required for the counting of the ultra small load particles, a simple geometric calculation was performed to extrapolate the data. The radius of all nano- composite spheres (R) processed was calculated aer aligning an arc in the TEM image processing soware (ImageJ) to the edge of the circular projection of each individual spheres on the micrographs. Next, a circular segment with a height ofhwas marked on the circular projection of each sphere by drawing a chord through two separate, distant points on the edge of projection; the area of the corresponding spherical cap can then be calculated by using the formula ofA_cap¼Rph. The number of Pt NPs within the area of the spherical cap is two times the number of countable particles on the circular segment (N). The total number of NPs on the surface of a silica sphere can then be estimated by ratioing the two areas:

Ntotal¼ Asphere

Acap 2N¼ 4R²p

Rph2N¼ 8RN h

Using the density data of platinum (rPt) and silica (rsilica), as well as the radius of the Pt NPs (r), the concentration wasnally calculated according to the formula

conc:¼ rPtVPt

r_PtVPtþr_silicaVsilica¼ r_PtNtotal4r³p 3 rPtNtotal4r³p

3 þrsilica4R³p 3 Fig. 1 Typical TEM image of the 1.6 nm Pt nanoparticles (A), SEM micrograph of the pristine St¨ober silica spheres (B) and TEM image of the Pt nanoparticles anchored onto the surface of a St¨ober silica sphere (C).

data were recorded for 20 minutes on each spot. The Pt concen- tration was calculated using the Si K_aand the Pt L_asignals.

2.3. Chemicals

All chemicals used in the synthesis experiments (tetraethox- ysilane, ethanol, ammonia, PtCl4, ethylene glycol, poly- vinylpyrrolidone, H2PtCl6$6H2O, Na-citrate, citric acid, NaBH4, and ascorbic acid) were of analytical grade or better quality.

Dilution of all solutions and dispersions was carried out with class I (trace analytical) quality deionized water from a VWR Puranity TU 6 UV/UF device. The cleaning of ICP-MS labware, as well as the acid dissolution of Pt NPs anchored to the silica particles solutions, was carried out by using the solution prepared from ultratrace quality nitric (67 wt%) and hydro- chloric (37 wt%) acids (Ultrapure Normatom, VWR). ICP-MS solution calibration standards were prepared from a certied, multielement stock solution (No. 8500-6948, Agilent Technolo- gies). The argon (99.996%) technical gas used was obtained from Messer (Hungary).

3. Results and discussion

3.1. Single particle ICP-MS measurements

The direct, individual measurement of the ultra small Pt NPs anchored onto the surface of the silica particles is not possible by spICP-MS due to the insufficient sensitivity of present day ICP-MS instruments (typical size detection limits for metallic NPs are between 10 and 30 nm). The signal pulse from each individual Pt NPs present in a single nanocomposite particle will add up and produce one Pt signal peak per nanocomposite.

Now we would like to point out that this cumulative signal can be used for the quantitation of Pt in the nanocomposite, if the Pt concentration is“large”enough. Our calculations show that if the concentration of Pt is over 0.01–0.02 wt% in the nano- composite, then the cumulative Pt signal should be well detectable by ICP-MS. Aer a size calibration of the spICP-MS using Pt particle standards, the detected cumulative peak intensity can be converted to the diameter value of an“equiv- alent” Pt NP and then the mass of Pt present in each nano- composite particle can be calculated (Fig. 2).

We would also like to support the feasibility of the above proposal in the present application by adding two comments.

First, spICP-MS measurements have already been shown to have an excellent repeatability (precision) due to the fact that the characteristic signal (mode of the signal histogram) is based on the measurement of more than ten thousand particles. Better than 1% RSD values can be achieved even when characteristic

will surely get completely ionized as the atomization and ioni- zation of the nanocomposite starts on its surface and progresses inwards during the residence of the particle in the plasma.

The above-mentioned concept was successfully tested with the measurement of the present Pt/SiO2nanocomposite, as can be seen in Fig. 3. Aer optimizing ICP-MS conditions with special attention paid to the plasma sampling depth,²³ size calibration was carried out (Fig. 3b) using the large Pt NPs prepared for this purpose (as described in Section 2.1). Aer evaluating the data using the three sigma methodology,^19,24we established that the Pt size detection limit is 17.2 nm.

Fig. 3a shows that the lognormal Pt NP peak in the signal histogram is well resolved from the background peak (caused by the spectral background and any residual dissolved Pt). The lognormalt is of good quality and is based on the analysis of thousands of nanocomposite particles. The mode of the particle peak (characteristic NP signal) was found to be equivalent to the signal from a 20.4 nm diameter spherical Pt particle. Knowing the size and density of both the support and the load particles, the Pt wt% concentration was calculated. This calculation produced a value of 0.0966 wt%, with a standard deviation of 0.0025 based on three repeated measurements.

3.2. Discussion of the accuracy of Pt concentration data In addition to spICP-MS, the determination of the concentra- tion of the Pt nanoparticles on the surface of the silica support was also carried out by four other analytical methods, namely solution-mode ICP-MS, SEM-EDS, TEM and XPS. The obtained results can be seen from Table 1. Three parallel measurements were performed with every method in order to calculate the standard deviation.

As it can be seen from the table, the concentration results are signicantly different. TEM and spICP-MS results agree reasonably well, but the concentrations provided by the other three methods are several times higher. In view of these differences, it is benecial to review the theoretical limitations of each individual analytical method in this application.

The analysis by the TEM imaging method is fairly simple to execute and requires only a small amount of solid sample. It is also very sensitive as very small (even sub nm) NPs can be counted. At the same time, the calculation relies on a number of extrapolations and preconditions including the following: (a) due to the large magnication needed to resolve the ultra small load NPs, only a portion of the total surface of the support particle is imaged, (b) the surface coverage is assumed to be the same on all sides of the support particle, (c) the surface coverage should not be too large to avoid clustering, (d) the NPs found on

the surface can only be assumed to be of the quality hoped (here:

Pt), since there is no direct information about the composition of the load NPs, and (e) the load NPs are assumed to be completely spherical, which is an assumption that rarely holds for very small NPs. In addition to this, the sample preparation/vacuum intro- duction as well as the processing of some dozens of images (the maximum in routine TEM practice) requires a considerable amount of time (hours). A bonus of the approach is that TEM also provides morphological information and can be universally applied to just any active NPs (at least under ultra clean condi- tions, so that assumption (d) can hold). Overall, the TEM imaging analysis is lengthy, and can provide a concentration

result that is fairly accurate, but not very precise (e.g.consider that the TEM result in Table 1 also has an RSD of over 30%).

spICP-MS requires a very small amount of dispersion for the analysis. The measurement is fast and simple, and usually takes onlyca.5 minutes, although it also requires the availability and measurement of size calibration samples (Pt). The nano- composite particles decompose in the ICP plasma and the Pt signals from the particles and from the precursor residues (solution background) are clearly differentiated, therefore the quantitative result is accurate and gives the true, nanocomposite-related Pt concentration. This is so because the dissolved analyte content of nanodispersions gives a peak following the Poisson function in the TRA histogram, whereas NPs give a separate peak that follows the lognormal statis- tics.^16,24This can help in avoiding large inaccuracies in quan- titative NP analysis. The analysis is also very precise, since it is based on the measurement of thousands of particles. The spICP-MS result obtained in the present study agrees well with the TEM result, and it is also the most precise one out of theve methods tested. A further benet of spICP-MS analysis is that the technique is also capable of delivering a number of addi- tional, valuable information about the dispersion sample, such as the number concentration and purity of the particles, as well as the presence of precursor residues.

Fig. 2 Left panel: schematic illustration of the decomposition and ionization process that a nanocomposite particle undergoes in the ICP plasma (deep blue: solid silica particle, light blue: Si and O ion cloud, deep red: surfacial solid Pt NPs, light red: Pt ion cloud). Right panel: if the concentration is large enough, the ultra small Pt NPs produce a cumulative signal, equivalent to that of a detectable larger NP.

Fig. 3 ¹⁹⁵Pt spICP-MS signal histogram recorded for the Pt/SiO2nanocomposite (left panel). Please note that the lognormal NP signal peak is well separated from the solution background signal. The characteristic intensity of the NP peak in the histogram corresponds to an equivalent NP size of 20.4 nm in the spICP-MS size calibration curve obtained with pure Pt NPs (right panel).

Table 1 Concentration of the Pt nanoparticles in the Pt/SiO2nano- composites determined by the five techniques. Standard deviation values are based on three parallel measurements

Technique

Pt concentration

(wt%) Standard deviation

Particle-mode ICP-MS 0.0966 0.0025

TEM 0.0824 0.0261

Solution-mode ICP-MS 0.2821 0.0030

SEM-EDS 0.4400 0.0152

XPS 0.7173 0.2867

Table2Acomparativetablefortheperformanceofthestudiedanalyticalmethodsusefulforthedeterminationofthemetalconcentrationoflarge-support nanocompositeparticles Requiredsample amount (mgormL) Totalanalysistime includingsample preparation, measurementand dataevaluation Overallstatistical reliabilityofthe result Potential interferencefrom precursorresidues Difficultyof calibrationand calculation Relationofthe informationdepth (ID)andthediameter ofnanocomposite particle(d)

Detectionlimitfor sizeoftheactive NPsinthe nanocomposite Solution- mode ICP-MS

10mgor2mLca.1hourExcellentLargeSimplen.a.Limitedbythesample amount(moresample allowsthedetection ofsmallerNPs) spICP-MS2mLof<105mL1 dispersion5minExcellentVerysmallSimpleID>dTypically1–5nm (dependsonthe elementandthe surfaceconcentration) XPS1–50mgca.1hourMediumMediumDifficultIDd<1nm SEM-EDSca.1mgca.1hourMediumMediumDifficultID>dca.2nm TEM1–2mgca.1hourGoodMediumSimplen.a.ca.0.5nm

Under the conditions used (e.g.acceleration voltage, working distance, angle of the detector, atomic massetc.) the SEM-EDS technique has a 5–7 mm information depth according to the Castaing's formula.²⁵ Usually, the matrix correction (ZAF correction) is needed for the exact concentration determination due to the fact that the number of X-ray photons counted at the detector depends on the atomic number of the elements, the adsorption of the X-rays and the uorescence effect. The sensitivity of SEM-EDS analysis is mediocre; the limit of detec- tion values is around a few thousand ppm (e.g.0.2–0.3 wt%),²⁶ meaning that in the present application, the technique was operated around its limit of detection. In addition to this, the accuracy is best if the sample has a smooth, polished surface (e.g.bulk sample), but in the case of particulate samples, the signal contribution from the“top”and“bottom”surfaces of the particles will not be the same, thus SEM-EDS requires a very careful calibration for quantitative measurements. Conse- quently, accurate results under routine conditions cannot be expected; here we found that the Pt content reported by SEM- EDS is ca. four times higher than the result from TEM imaging calculations. The best spatial resolution of EDS is about 1mm, which might allow for the individual analysis of each Pt/SiO₂nanocomposite if the particles are well separated on the substrate, but in order to have a larger analytical signal, typically larger apertures are used (we used 100mm). This brings about the problem of potential interference from precursor residues which can contaminate the substrate in areas between the nanocomposite particles during sample preparation. This effect can result in a signicant positive bias in the SEM-EDS results. SEM-EDS requires only a very small amount of solid sample for the analysis. The analysis time is long ($one hour), similar to TEM imaging, considering sample preparation, vacuum introduction and the need for longer exposition times when working at low concentrations, as well as the complicated data processing. In summary, SEM-EDS is not very suitable for the accurate analysis of nanocomposites with large support particles and/or low loadings.

XPS is a truly surface analytical technique; its information depth is about 10 nm only. It is somewhat more sensitive than SEM-EDS (a factor of 2–3), but the spatial resolution is poorer (some tens of mm).²⁶ This again permits interference from precursor residues on the substrate, which may result in a positive error in quantitative measurements. Due to its shallow information depth and because of geometric condi- tions, XPS is not able to detect the majority of the mass of the support particle, which causes a strong overestimation of the wt% Pt concentration. This can explain the nearly 9 times higher XPS result compared to TEM. The precision was also found to be poor, as much as 40% RSD. The analysis time is comparable to that of TEM or SEM-EDS ($one hour).

Solution-mode ICP-MS is a very sensitive technique. Its ng L¹(ppt) level limit of detection values allow the measurement of 0.01 wt% loadings or less, depending on the elements (isotopes) to be detected. Almost all elements in the periodic system, with the exception of a few nonmetallic elements, can be measured.²⁷Nevertheless, ICP-MS requires the introduction of solution samples, therefore extensive chemical sample

preparation (e.g. pressure or sonication assisted acid dissolu- tion, etc.) is involved in the measurement. This makes the analysis time long (hours), especially if the dissolution proce- dure also needs to be developed specically for the nano- composites, and also increases the required solid nanocomposite sample amount to the mg level (an amount that can be accurately weighed and handled). The preparation and measurement of solution calibration samples is also needed, which again adds extra time to the analysis, but the quantitative results will also be more accurate this way. It has to be mentioned that solution-mode ICP-MS measurements are also prone to interference, the most severe here being the interfer- ence from precursor residues and dissolution reagent contami- nants. These effects can give rise to a signicant positive error in the result of the determination. In the present application, solution ICP-MS gave a Pt concentration result that is nearly three times higher than the TEM result, in spite of the ultra trace analytical conditions used. The precision was excellent, about 1% RSD.

Table 2 summarizes some features of the ve analytical methods tested relevant in this application.

4. Conclusions

Five analytical techniques were tested in the application of the determination of the Pt concentration in a novel Pt/SiO2nano- composite (St¨ober silica particles decorated with ultra small, 1.6 nm diameter, Pt NPs). Four of these analytical methods (SEM-EDS, TEM imaging, XPS and solution-mode ICP-MS) are well established methods oen used for the characterization of nanoparticles. The h method, single particle ICP-MS, is a novel, upcoming technique, which has not yet been tested earlier in the literature for nanocomposite characterization.

Aer performing repeated analyses on the as-synthesized nanocomposite and discussing the limitations of the accuracy of each method, we found that spICP-MS has an excellent potential in nanocomposite characterization. The spICP-MS analysis is fast; it requires only a small amount of sample, largely free from interference and gives accurate and precise results that agree well with the results from TEM imaging analysis. We would like to emphasize that a great benet of using spICP-MS over the classical solution-mode ICP-MS for the quantitative analysis of nanodispersions is that spICP-MS can differentiate between the analyte contents present in ionic (dissolved) form and in particle form. This can help in avoiding large inaccuracies in quantitative NP analysis. We also success- fully demonstrated, for therst time in the literature, that the cumulated spICP-MS signal from ultra small, individually not detectable NPs present on the surface of a nanocomposite allows accurate quantitation. Our results indicate that a careful choice of the measurement technique has to be made when deter- mining the load concentration in nanocomposites.

Acknowledgements

This work was supported by the J´anos Bolyai Research Schol- arship of the Hungarian Academy of Sciences and the New

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